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1645 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 5, p. 1645-1651, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n5a2020-48197 

IRRIGATION MANAGEMENT IN SOYBEAN CROPS INFLUENCES THE 
OCCURRENCE OF NEMATODES IN THE SOIL 

 
MANEJO DE IRRIGAÇÃO NA CULTURA DA SOJA INFLUENCIA A OCORRÊNCIA 

DE NEMATOIDES NO SOLO 
 

Ricardo GAVA¹; Thiago Ramos da SILVA1; Mayara Fávero COTRIM2; 
 Alexandra Botelho Lima ABREU3; Jefferson Luis ANSELMO4; Paulo Eduardo TEODORO1* 
1. Universidade Federal de Mato Grosso do Sul, Chapadão do Sul, MS, Brasil; 2. Universidade Estadual Paulista “Julio de Mesquita 

Filho”, Ilha Solteira, SP, Brasil; 3. FMC Corporation, Chapadão do Sul, MS, Brasil; 4. Fundação de Apoio a Pesquisa Agropecuária de 
Chapadão, Chapadão do Sul, MS, Brasil. *eduteodoro@hotmail.com  

 
ABSTRACT: One of the main limitations of soybean production is related to water availability and 

organisms found in the soil. Under the hypothesis that soil moisture may influence the nematode population, 
this study aimed to verify the occurrence of nematodes associated with different irrigation management in 
soybean crops. The experiment was carried out in a randomized block design. Treatments consisted of a subplot 
scheme, with four replications. The plots consisted of ten irrigation managements divided into five irrigation 
frequencies (1,2,3,4, and 5 days) and five additional water depths (25, 50, 75, 100, and 125% of crop 
evapotranspiration – Etc). The subplots were composed of four different soybean cultivars (NA 5909 RR, AS 
3680 IPRO, and Desafio RR ePower IPRO). The experiment analyzed the variables plant height, first pod 
insertion, number of plants, moisture, hundred-grain weight, yield, and occurrence of nematode eggs and 
adults. Nematodes influence all the production components analyzed, affecting mostly the hundred-grain 
weight, especially the nematode Helicotylenchus sp., although the Meloidogyne sp. population was larger. The 
phytonematode population reduces with the increase in soil moisture to levels close to the saturation, indirectly 
influencing the yield increase. 

 
KEYWORDS: Phytonematode. Glycine Max L. Water depths. 

 
INTRODUCTION 

 
Brazil and Argentina account for 50% of 

world soybean production and exports (FAO, 2017). 
Soybean is widely used in human and animal diet, 
and thus, it has great economic relevance. The high 
yield potential achieved by soybean crop is mostly 
due to the constant search for new technological 
solutions. 

In the 2016/2017 season, grain crops were 
cultivated in 60.9 million hectares, which accounted 
for the largest area intended to grain crops in 
Brazilian history (CONAB, 2018). This area is 
concentrated in soybean and maize crops, 
corresponding to 85% of the total área cultivated 
with grains in the country. However, one of the 
main limiting causes of global agricultural 
production is the occurrence of pests and 
diseases. In this context, phytonematodes are one 
of the most important pests due to their difficult 
control (DIAS-ARIEIRA, 2011). In soybean 
crops, nematodes can be found both in the soil and 
plant roots and may cause severe damage to the 
crop. According to Inomoto (2006), the most 
common nematode genera found in Brazilian 
soybean crops are Meloidogyne javanica, M. 

Icognita, and M. Arenaria (the root-knot 
nematodes); Heterodera glycines (the soybean cyst 
nematode - SCN); Rotylenchulus reniformis; and 
Pratylenchus brachyurus (the lesion nematode). 
These species have been observed in different 
Brazilian regions, mostly in the Central region, 
where the problem has increased, causing severe 
damages in soybean crops in the stated of Mato 
Grosso do Sul and Goias (EMBRAPA, 2011). 

Abreu & Borges (2016) studied the region 
between the states of Mato Grosso, Goiás, and Mato 
Grosso do Sul and reported the lesion nematodes 
(Pratylenchus brachyurus) in most samples (74% in 
the 2014/15 season). The root-knot nematodes 
(Meloidogyne javanica, Meloidogyne icognita, 
Meloidogyne arenaria) and the soybean-cyst 
nematode (Heterodera glycines) were also found in 
the samples. Heterodera glycines was found in 
larger number in the 2015/16 season when 
compared with previous seasons. 

The soil moisture between 40 and 60% of 
the field capacity is considered as optimal for the 
nematode activity. Greater populations are usually 
found in moist and well-aerated soils, while 
saturated soils are usually unfavorable to nematode 
activity (LAUGHLIN; LORDELLO, 1977). The 

Received: 08/04/19 
Accepted: 30/12/19 



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Biosci. J., Uberlândia, v. 36, n. 5, p. 1645-1651, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n5a2020-48197 

nematodes control in the soil associated with 
irrigation is a viable alternative for producers since 
the population of several phytonematodes species is 
significantly reduced due to oxygen limitation and 
soil pH (MASSAROTO & YAMASHITA, 2011). 
This study aimed to assess the occurrence of 
nematodes in soybean crops under different 
irrigation management. 
 
MATERIAL AND METHODS 
 

The experiment was carried out at Fundação 
de Apoio à Pesquisa Agropecuária de Chapadão, 

located in the municipality of Chapadão do Sul, MS 
(lat. 18°46'49 "S; long. 52°38'51"W; alt. 810 m asl.) 
after three harvests of the soybean and maize 
production system, under center pivot. According to 
the Köppen classification (PEEL et al., 2007), the 
climate of the region is Aw type (tropical with dry 
winter and rainy summer), with an average annual 
temperature of 25 °C and an average annual rainfall 
of 1800 mm. The soil was classified as Clayey 
Dystrophic Red Latosol and the physical and water 
characteristics required for the correct irrigation 
management were obtained (Table 1). 

 
Table 1. Physical and water characteristics of the soil  

       Granulometric fractions Texture 
Layer FC PWP WCA ρ Pd TP 

(cm) (cm3 cm-3) (mm cm-1) (g cm-3) (%) Sand Silt Clay 
 

       
(%) 

 
0 – 15 0.413 0.282 1.76 1.34 2.65 53.6 39.24 6.68 54.08 

Clayey 
15 – 30 0.383 0.262 1.74 1.44 2.65 48.4 36.76 4.56 58.68 

FC - Moisture in the field capacity at the matric potential (ᴪm) of 0.3 atm; PWP - Permanent wilting point in ᴪm of 15 atm; WCA – 
available water capacity;  ρ - Soil bulk density; TP -  total soil porosity; Pd– Soil particle density 
 

Soybean seeds were treated with fungicide 
(Pyraclostrobin) and insecticide (Fipronil) at a dose 
of 200 mL per 100 kg of seeds. Seeds were sown on 
October 19, 2016, in a no-tillage system, with a 
spacing of 0.45m between rows. Plots were 
composed of five sowing rows. The useful area 
consisted of the three central rows (3,6 m2). 

Fertilization consisted of 150 kg ha-1 of 
NPK (11-52-00) applied in the sowing row, and 150 
kg ha-1 of KCl applied as topdressing. The irrigation 
frequencies were 1, 2, 3, 4 and 5 days, calculated by 
the Crop Evapotranspiration (Etc) accumulated in 
the interval between irrigations. The water depths 

(25, 50, 75, 100, and 125% of ETc) were applied 
only when the crop reached the lower limit of the 
actual soil water capacity (ASWSC) (ALLEN et al., 
1998). The experiment was carried out in a 
complete randomized block design, in a subplot 
scheme. The central pivot was divided into ten plots 
(five irrigation frequencies and five additional water 
depths), with four replications. The plots were 
subdivided into four subplots, where the different 
soybean cultivars were planted (NA 5909 RR (C1), 
AS 3680 IPRO (C2), Desafio RR (C3) e POWER 
IPRO (C4) (Table 2). 

 
Table 2. Plant population and soybean cycle. 
Cultivar Owner Commercial name Cycle/Days Recommended population 

    (seeds m-1)  (Thousand plants ha1) 
C1 Nidera NA 5909 RR Early           100 23                     511.111 
C2 Agroeste AS 3680 IPRO Early           105 20                     444.444 
C3 Brasmax Desafio RR Intermediate  115 24                     533.333 
C4 Brasmax Power IPRO Intermediate  118 18                     400.000 

*seeds m-1 – number of seeds per linear meter 
 

Table 3 shows the number of irrigations, 
total water depth applied per treatment, and the 
accumulated ETc in the period. Since the 
experiment was carried out in the field, some 
rainfall events were registered, which hindered the 
effect of the treatments that went through larger 
intervals without irrigation. 

The ETo was obtained by the Penman-
Monteith-FAO method, according to Allen et al. 
(1998), using data from the automatic 
meteorological station of the Instituto Nacional de 
Meteorologia (INMET), located in the municipality 
of Chapadão do Sul, MS, Brazil. The ETc was 
obtained by multiplying the Reference 



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Irrigation management…  GAVA, R. et al. 

Biosci. J., Uberlândia, v. 36, n. 5, p. 1645-1651, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n5a2020-48197 

Evapotranspiration (ETo) by the Crop Coefficient 
(Kc). The crop coefficients and the root system 
depth of each subperiod were defined according to 

the recommendations of Doorenbos & Kassam 
(1994).  

 
Table 3. Number of irrigations, total water depth applied and accumulated evapotranspiration of treatments. 

Treatments  Number of irrigations Total water depth 
applied 

Accumulated ETc   

  mm mm 

Frequency 

1 day 36 176 

370 

2 days 13 123 

3 days 8 103 

4 days 7 111 

5 days 4 65 

Water Depth (% ETc) 

25 5 26 

370 

50 5 46 

75 5 66 

100 5 86 

125 5 106 

 
The variable plant height (PH) was analyzed 

by measuring the distance from the soil and the end 
of the main stem. First pod insertion (FPI) was 
analyzed by measuring the distance from the soil 
and the first pod. Number of plants (NP) was 
determined by counting all the plants. Hundred-
grain weight (HGW) was determined by weighing 
one hundred grains. Grain yield (Y) was analyzed 
by harvesting the central rows of the plot, totaling 
3.6 m2 of experimental area. HGW and Y obtained 
had their results corrected to 13% of moisture 
(storage standard), determined by an electronic 
sampler at the evaluation time. 

For the nematological evaluation, samples 
were collected at three different points within each 
subplot to compose one single sample per treatment, 
totaling 160 samples. Samples were collected when 
cultivars were at full bloom (EMBRAPA, 2009). 
The analyses were carried out by separating the 
roots to remove 100 cm3 of the soil used for 
nematode extraction, followed by the sieving and 
centrifugal flotation processes (JENKINS, 1964). 
Roots were washed, and 10g were used the 
nematodes extraction, followed by the trituration, 
sieving, and centrifugation (COOLEN &D'HERDE, 
1972). Nematodes were counted with the aid of the 

Peters Chamber, under a light microscope, for the 
identification and quantification of specimens.  

The means of each treatment were subjected 
to the principal component analysis to verify the 
interrelationship between the production 
components and their association with the 
treatments. For data analysis, the Pearson’s 
correlations between the production components 
were estimated. The functional relationship between 
the estimates of coefficients of correlation among 
the traits was graphically expressed by a correlation 
network, where the proximity between the nodes 
(traces) is proportional to the absolute value of the 
correlation between these nodes. The thickness of 
the edges was controlled by applying a cut-off value 
of 0.60, which means that only |rij| ≥ 0.60 have their 
edges highlighted. Positive correlations were 
highlighted in green, and negative correlations were 
highlighted in red. All analyses were carried out 
using the Rbio software (BHERING, 2017). 
 
RESULTS AND DISCUSSION 
 

Results of the water balance (WB) of the 
experimental period revealed two moments when 
the soil moisture surpassed the lower limit of readily 



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Biosci. J., Uberlândia, v. 36, n. 5, p. 1645-1651, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n5a2020-48197 

available water, given by the ASWSC (Figure 1). 
The first moderate deficit occurred between 55 and 
67 DAE (days after emergence) in early cultivars at 
the phenological stage R5.1, and in late cultivars, at 
the stage R4. The second moderate deficit occurred 

at the end of the cycle, between 126 and 131 DAE, 
when the early cultivars had already completed their 
cycles, and the late cultivars were at the final stage 
of grain filling. 

 

 
Figure 1. Rainfall at the experimental area, residual water content (RWC), readily available water (RAW), and 

soil water storage (Storage).  
 

Figure 1 shows the soil moisture variation in 
millimeters, indicated by the Storage line; the AWC 
values ranged according to the development of the 
root system, stabilizing at 54.7 mm, at the effective 
depth of 0.35 m, established at the end of the 
vegetative stage (Allen et al., 1998).  

The principal component analysis confirmed 
the accumulation of 71% of the total observed 
variability (Figure 3). Both irrigations with an 

interval of one and two days increased HGW and Y, 
respectively, demonstrating that high frequencies 
irrigations directly correlated with the principal 
components. Due to the high incidence of rainfall 
over the crop cycle, the plants' acclimatization was 
mostly subject to cloudy days with high humidity; 
therefore, treatments with high irrigation frequency 
resembled the actual conditions to which the plant 
was subject. 

 

 
Figure 2. Principal components analysis for the variables plant height (PH), first pod insertion (FPI), number of 

plants (NP), grain moisture (GM), hundred-grain weight (HGW), nematode (NEM), and yield (Y) 
evaluated in different irrigation managements. 

 



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Irrigation management…  GAVA, R. et al. 

Biosci. J., Uberlândia, v. 36, n. 5, p. 1645-1651, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n5a2020-48197 

Among the water depths, levels 9 and 10 
increased PH and FPI. Conversely, the higher 
occurrence of nematodes was observed in larger 
intervals and smaller water depths, considered to be 
favorable to the growth and emergence of 
nematodes in general. Laughlin & Lordello, (1977) 
confirm that the soil moisture between 40 and 60% 
of the field capacity is considered as optimal for 
nematodes activity and that saturated soils impair 
the growth of the nematode. Therefore, the high soil 
moisture reduced the nematodes, indirectly 
influencing yield. Negretti et al. (2014) studied rice 
crops under irrigation system and observed the 
reduction in the nematodes reproduction and 
number of root-knot for other genera of nematodes 
(A. philoxeroides, O.  sativa -ARV, E. crusgalli, C. 
difformis, C.  iria, and F.  miliacea) 

The correlation analysis revealed that 
cultivars C3 and C4 influenced yield. The different 
managements tested showed similar yield results, 

which can be explained by the water balance of the 
period (large amount of rainfall and small numbers 
of irrigations). Conversely, FPI and NP are directly 
related to cultivar C4. Brida et al. (2017) explain 
that the nematode P. brachyurus can penetrate and 
grow in roots regardless of the soybean cultivar 
analyzed. Matsuo et al. (2012) and Bellé et al. 
(2017) found differences between soybean and 
sugarcane genotypes, respectively, and classified 
them as resistant and moderately resistant to 
Heterodera glycines, Meloidogyne javanica, and 
Pratylenchus zeae, respectively.  

The PH and HGW had a high negative 
correlation (Figure 3), indicated by the thick red 
line, showing that the taller the plants, the lower was 
the value of hundred-grain weight. Conversely, FPI 
and NP showed a positive correlation of high 
magnitude, indicated by the green line, indicating 
that the larger the plant population, the higher was 
the first pod insertion. 

 

 
Figure 3. Correlation network between different irrigation managements for plant height (PH), first pod 

insertion (FPI), number of plants (NP), grain moisture (GM), hundred grain weight (HGW), yield 
(Y), nematode eggs, and nematodes population [Pratylenchus brachyurus (N1), Meloidogyne sp. 
(N2), and Helicotylenchus sp. (N3)]. Positive correlations were highlighted in green, and negative 
correlations were highlighted in red; the thickness of the traces indicates the magnitude of the 
correlation. 

 
Nematodes negatively influenced all the 

yield components. According to Dias (2011), the 
implantation of the no-tillage system requires great 
caution in choosing the successor crop, and most of 
the soybean areas are succeeded by maize. 
Therefore, both soybean and maize crops are highly 
susceptible to P. Brachyurus. The occurrence of 
Helicotylenchus sp (N4) interfered with HGW. 
According to Garbin & Costa (2015), low rainfall 
rates are associated with high incidence of 
Helicotylenchus sp. in the soil and roots. This 

species is associated with most soil analyses carried 
out under conditions similar to that of the state of 
Mato Grosso. Thus, studies on damages and losses 
require attention. The eggs (N1) showed a strong 
and positive correlation with the genus Meloidogyne 
sp. (N3), suggesting a higher occurrence of this 
species. Fontana et al. (2018) state that 
Meloidogyne sp. eggs are protected from natural 
enemies and from the lack of moisture by the egg 
amount secreted by females. This is not the case of 



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Pratylenchus brachyurus eggs, which are deposited 
in the soil.  

 
CONCLUSIONS 

 
Nematodes influence all the yield 

components analyzed. Hundred-grain weight is 

primarily affected, mainly by the nematode 
Helicotylenchus sp., although the population of 
Meloidogyne sp. is larger.  

The phytonematode population reduces with 
the increase in the soil moisture to levels close to 
saturation, indirectly increasing yield. 

 
 

RESUMO: Uma das principais limitações da produção de soja está relacionada à disponibilidade de 
água e organismos encontrados no solo. Sob a hipótese de que a umidade do solo possa influenciar a população 
de nematoides, este estudo teve como objetivo verificar a ocorrência de nematóides associados a diferentes 
manejos de irrigação em lavouras de soja. O experimento foi conduzido em delineamento de blocos 
casualizados. Os tratamentos consistiram de um esquema de subparcelas, com quatro repetições. As parcelas 
consistiram de dez manejos de irrigação divididos em cinco freqüências de irrigação (1,2,3,4 e 5 dias) e cinco 
lâminas d'água (25, 50, 75, 100 e 125% da evapotranspiração da cultura - Etc). As subparcelas foram 
compostas por quatro diferentes cultivares de soja (NA 5909 RR, AS 3680 IPRO e Desafio RR ePower IPRO). 
O experimento analisou as variáveis altura da planta, inserção da primeira vagem, número de plantas, umidade, 
peso de cem grãos, produtividade e ocorrência de ovos de nematoides e adultos. Os nematóides influenciam 
todos os componentes de produção analisados, afetando principalmente o peso de cem grãos, especialmente o 
nematódeo Helicotylenchus sp., Embora o Meloidogyne sp. população era maior. A população de 
fitonematóides reduz com o aumento da umidade do solo para níveis próximos à saturação, influenciando 
indiretamente o aumento da produtividade. 

 
PALAVRAS-CHAVE: Fitonematodes. Glycine Max L. Lâminas de água. 

 
 
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